The invention discloses a robotic dexterous hand including a plurality of finger mechanisms, the finger mechanisms comprises: an actuator; a connecting element with one end fixed to the actuator; a plurality of fingers including a plurality of knuckles, the knuckle includes a fixed knuckle positioned at the other end of the connecting element, the fixed knuckles are arranged in parallel and jointly form a palm of the robotic dexterous hand; wherein the actuator drives the flexion of the fingers to perform the gripping of a target object. The fingers and the palm are built from the multiple knuckles having a same structure. Design is required merely for the structure of a single knuckle, the need for discretely designing the structure of the fingers and that of the palm is obviated, thus greatly reducing the types of components, at the same time, simplifying the structure, and favoring the production and management.
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1. A robotic dexterous hand, the robotic dexterous hand includes a plurality of finger mechanisms, each of the finger mechanisms comprising:
an actuator;
a connecting element, one end of the connecting element is fixed to the actuator;
at least one fingers, the finger includes a plurality of knuckles which are successively and rotatably connected head-to-tail, the knuckles include& a fixed knuckle positioned at the other end of the connecting element, the fixed knuckles of the fingers of the finger mechanisms are arranged in parallel and jointly form a palm of the robotic dexterous hand; wherein
the actuator drives the flexion of the fingers of the finger mechanisms to perform the gripping of a target object,
wherein each of the knuckles includes a base module, the base module includes a main body, a first connecting portion and a second connecting portion, the first connecting portion and the second connecting portion are defined on both ends of the main body, the first connecting portion of one of two adjacent knuckles flexibly and rotatably articulates to the second connecting portion of the other knuckle.
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This application is a national stage filing under section 371 of International Application No. PCT/CN2016/103856 filed on Oct. 28, 2016, which is published in Chinese on May 3, 2018 as WO2018/076304, the disclosure of which are hereby incorporated by reference in their entirety.
The invention pertains to the field of robotics, and in particularly relates to a robotic dexterous hand.
The robotic dexterous hand technology plays an important role in the field of robotics, domestic and foreign scholars have done a lot of researches on robotic dexterous hand technology and produce numbers of studies after a long-time development, such as HTI/DLR hand, NASA hand, SHADOW hand, etc. The related technologies mainly focus on the mechanical structure, driving, sensing and integration, etc. For example, the SHADOW hand uses five fingers controlled by pneumatic muscles; HIT/DLR and NASA hands are driven by multi-motors, the driving element is arranged on the finger joints and the palm.
The palm and the fingers of the robotic dexterous hand in the prior art are usually separately designed, the structure of the fingers and the palm are so complex resulting numerous components. As different dies and molds are needed to produce different components, it is not only inconvenient for inventory management with higher cost, but also not easy for assembly and maintenance, the practicality and applicability of the dexterous hands are greatly reduced.
The purpose of the invention is to solve the problems in the prior art, including the complex structure of the robotic dexterous hand with numerous components and inconvenience for manufacture management and assembly.
The present invention is provided to solve the above problems.
In accordance with an aspect of the embodiment, there is provided a robotic dexterous hand. The robotic dexterous hand includes: a plurality of finger mechanisms, each of the finger mechanisms comprises: an actuator; a connecting element, one end of the connecting element is fixed to the actuator; a plurality of fingers, the finger includes a plurality of knuckles which are successively and rotatably connected head-to-tail, the knuckle includes a fixed knuckle positioned at the other end of the connecting element, the fixed knuckles of the fingers are arranged in parallel and jointly form a palm of the robotic dexterous hand; wherein the actuator drives the flexion of the fingers to perform the gripping of a target object.
The fingers and the palm of the robotic dexterous hand are built from the multiple knuckles having a same structure. Hence, design is required merely for the structure of a single knuckle, the need for discretely designing the structure of the fingers and that of the palm is obviated, thus greatly reducing the types of components of the robotic dexterous hand, at the same time, simplifying the structure of the robotic dexterous hand, and favoring the production and management.
Meanwhile, as the knuckle is a modular component, the users can construct their own fingers of different quantities and their own fingers consisting of different quantities of the knuckles based on their own needs, different numbers and different length of the fingers are also needed to meet various requirements for various objects, which greatly increases the flexibility of the configuration of the robotic dexterous hand to meet the needs of different users.
The invention will be described with reference to the accompanying drawings. These and/or other aspects and advantages of the invention will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings.
The invention will be further described below in details with reference to the figures and embodiments.
Referring generally to
Each of the fingers 23 includes a plurality of knuckles 232 which are successively and rotatably connected head-to-tail. The knuckle 231 of the finger 23 includes a fixed knuckle 232 positioned at the other end of the connecting element 22. In the embodiment of the present invention, the fixed knuckle 232 is located on one end of the finger 23. The fixed knuckle 232 of each finger 23 is secured to the connecting element 22 during the process of installing, the fixed knuckles 232 of the fingers 23 are arranged in parallel and jointly form a palm 30 of the robotic dexterous hand 100.
In other words, the fingers 23 and the palm 30 of the robotic dexterous hand 100 are built from the multiple knuckles 231 having a same structure. Hence, design is required merely for the structure of a single knuckle 231, the need for discretely designing the structure of the fingers 23 and that of the palm 30 is obviated, thus greatly reducing the types of components of the robotic dexterous hand 100, at the same time, simplifying the structure of the robotic dexterous hand 100, and favoring the production and management of the components.
Meanwhile, as the knuckle 231 is a modular component, the users can construct their own fingers 23 of different quantities and their own fingers 23 consisting of different quantities of the knuckles 231 based on their own needs, different numbers and different length of the fingers 23 are also needed to meet various requirements for various objects, which greatly increases the flexibility of the configuration of the robotic dexterous hand 100 to meet the needs of different users.
In the embodiment of the present invention, the robotic dexterous hand 100 includes three finger mechanisms 20, one of the finger mechanisms 20 includes two fingers 23, the two fingers 23 extend separately from two ends of the fixed knuckles 232. Each of the other two finger mechanisms 20 includes only one finger 23 extending from one end of the fixed knuckles 232.
In other embodiment, the users can deploy different quantities of finger mechanisms 20 and the corresponding quantities of fingers 23 as required. For example, the robotic dexterous hand 100 includes three finger mechanisms 20 in the present embodiment, five or six fingers 23 are alternatively adopted in other embodiments. The fingers 23 extend separately from both ends of two fixed knuckles 232 when the number of the fingers 23 is five, the finger 23 extends from one end of another fixed knuckle 232. Two fingers 23 extend from two ends of each fixed knuckle 232 when there are six fingers 23.
In other words, the users can add more knuckles 231 extending from the fixed knuckles 232 of the present invention as required to form an additional finger 23, which greatly increases the applicability of the fingers arrangement of the robotic dexterous hand 100.
In the present embodiment, the number of knuckles 231 of each finger 23 is three. In other alternative embodiment, the users can deploy different quantities of knuckles 231 to lengthen or shorten each finger 22, for example, one more knuckle 231 can be added to each finger 23, or one more knuckle 231 can be added to only one finger 23.
As described above, the finger 23 and the palm 30 are made up of modular knuckles 231 according to the robotic dexterous hand 100 of the present invention, the users can configure different quantities of fingers 23, different length of fingers 23 and different sizes of palms 30 to meet various requirements, which greatly increases the applicability and the flexibility of the robotic dexterous hand 100.
Along with
Further, the first connecting portion 202 includes a pair of first extension beams 2021 spaced from each other, the first extension beams 2021 extend from one end of the main body 201. The second connecting portion 203 includes a pair of second extension beams 2031 spaced from each other, the second extension beams 2031 extend from the other end of the main body 201. As shown in
In the present embodiment, the first spring 81 is a torsion spring.
Referring to
In the present embodiment, the knuckle 231 at the free end of the finger 23 is defined as a distal knuckle 233 for better understanding, the knuckle 231 adjacent to the fixed knuckle 232 is defined as a proximal knuckle 234. During the assembly, one end of the first driven belt 25 is fixed to the distal knuckle 233, the other end extends successively from the distal knuckle 233 along the other knuckles 231 connecting to the distal knuckle 233 until beyond the proximal knuckle 234, as shown in
The first servo 1 drives the first driven belt 25 to draw all the knuckles 231 between the proximal knuckle 234 and the distal knuckle 233 to link with the distal knuckle 234 when the robotic dexterous hand 100 is at work.
More specifically, as shown in
Referring to
The first driven belt 25 mentioned above is assembled in the direction from the distal knuckle 233 towards the proximal knuckle 234, it can be understood that the first driven belt 25 can be assembled in the direction from the proximal knuckle 234 towards the distal knuckle 233.
As an improvement of the present invention, the finger 23 further includes a first spring tube 26. One end of the first spring tube 26 is inserted into the proximal knuckle 234 when assembled, the other end of that passes through the connecting element 22 and enters the shell 211 of the actuator 21. The portion of the first driven belt 25 having the same path as the first spring tube 26 is received in the first spring tube 26. That is to say, the first spring tube 26 guides the extension path of the first driven belt 25, the first spring tube 26 provides a guiding path for the first driven belt 25 to guide the movement of the first driven belt 25, and it plays the role of replacing the pulley system to transmit power for a flexible driving.
Further, as illustrated in
When the fingers 23 perform gripping, the actuator 21 pulls the first driven belt 25, at the same time, the first spring tube 26 and the first driven belt 25 are in friction with each other, the first spring tube 26 is in a strained state. The outlet 207 extends obliquely with respect to the outer case 2341 of the proximal knuckle 234, thus, the inclined outlet 207 provides a predetermined and reasonable angle for securing the first spring tub 26 so that the first spring tube 26 possess a reasonable curved posture in the space to reduce the additional resilience caused by the first spring tube 26 against the fingers 23 when the fingers 23 are stretched.
When the fingers 23 return, the actuator 21 drives the first driven belt 25 to loosen, the fingers 23 return to initial position under the driving of the first spring 81 located between the adjacent knuckles 231.
The robotic dexterous hand 100 of the present invention can effectively prevent the first spring tube 26 from counteracting against the knuckle 231 with larger elastic coefficient by setting the outlet 207 of the outer case 2311 of the knuckle 231 to be inclined, so the knuckle 231 can be successfully returned to its original position. At the same time, it can also effectively avoid the possible slippage of the first spring tube 26.
In the present embodiment, the first spring tube 26 and the outlet 207 are interference fitted, the first spring tube 26 and the outlet 207 are fixed by friction.
In the present embodiment, the center line of the outlet 207 is tangent to the first pulley 60 of the corresponding knuckle 231. In use, the first driven belt 25 is at the center of the first spring tube 26, which effectively reduces the resistance between the first driven belt 25 and the inner wall of the outlet 207, so that the knuckle 231 can perform the flexion successfully.
In the present embodiment, the portion of the first spring tube 26 coinciding with the actuator 21 is pre-embedded in the shell 211 of the actuator 21. The first spring tube 26 is pre-embedded in the shell 211 of the actuator 21, so that it effectively guides the extension path of the first driven belt 25, and it is also beneficial for the organization of the first driven belt 25 by the robotic dexterous hand 100, and improves the transmission efficiency by setting the curvature of the first spring tube 26 within the shell 211. The finger mechanism 20 further includes a guiding plate 24, the guiding plate 24 is defined on the exterior of the shell 211 of the actuator 21, which corresponds to the portion of the first spring tube 26 entering the shell 211 of the actuator 21. The outer surface of the guiding plate 24 is inclined with respect to the shell 211 of the actuator 21, the first spring tube 26 abuts against the outer surface of the guiding plate 24, releases the reaction force against the finger 23 in the oblique direction of the guide plate 24 and extends into the shell 211 of the actuator 21.
During the assembly, the first spring tube 26 passes through the outlet 207 and enters the actuator 21 via the guiding plate 24, the guiding plate 24 pushes the first spring tube 26 away from the actuator 21, so as to provide a larger bending space for the first spring tube 26 which allows the first spring tube 26 move smoothly with less frictional resistance when the knuckles 231 are unbent. At the same time, it can also effectively avoid the possible slippage of the first spring tube 26.
Referring to
In one condition, the first spring tube 26 is attached along the first inclined surface 241, a larger bending space is provided by means of the inclined angle produced by the first inclined surface 241, so that it allows the first spring tube 26 to move smoothly with less frictional resistance when the knuckles 231 are unbent.
In another embodiment of the present invention, the guiding plate 24 includes a first inclined surface 241 and a second inclined surface 242 intersecting with the first inclined surface 241, the distance between the first inclined surface 241 and the corresponding shell 211 of the actuator 21 and the distance between the second inclined surface 242 and the corresponding shell 211 of the actuator 21 gradually decrease along the extension path of the first spring tube 26 into the actuator 21, the first spring tube 26 abuts against the first inclined surface 241 or the second inclined surface 242. Due to the second inclined surface 242, an abutting space is provided for the first spring tube 26 in the direction vertical to the extension path as the first spring tube 26 extends into the actuator 21. That is to say, the first spring tube 26 can abut against the first inclined surface 241 or the second inclined surface 242, enough bending space is guaranteed regardless of either surface the first spring tube 26 abuts against according to the gripping gesture or other factors. When the first spring tube 26 directly abuts against the shell 211 of the actuator 21 and the fingers 23 perform some actions, such as stretching the fingers 23 towards the direction of the actuator 21, the operations of the fingers 23 may be affected as the force between the first spring tube 26 and the shell 211 counteracts against the fingers 23, as a result, the problem is solved. It can be understood that the users can adjust the leaning surface of the first spring tube 26 according to requirements.
As shown in
Further, the finger mechanism 20 further includes a second spring tube 28, one end of the second spring tube 28 is inserted in to the outlet 207 of the fixed knuckle 232, the other end passes through the connecting element 22 and enters the shell 211 of the actuator 21, the portion of the second driven belt 27 having the same path as the second spring tube 28 is received in the second spring tube 28, the second spring tube 28 guides the extension path of the second driven belt 27.
The second spring tube 28 has the same function as the first spring tube 26, as the outlet 207 of the fixed knuckle 232 is inclined, the second spring tube 28 has enough space when the actuator 21 drives the second driven belt 27 to loosen, the second spring tube 28 can smoothly return to its original position under the action of its own elasticity.
Similarly, the portion of the second spring tube 28 coinciding with the actuator 21 is pre-embedded in the shell 211 of the actuator 21, so that it is beneficial for the organization of the second driven belt 27 by the robotic dexterous hand 100. The transmission efficiency is improved by setting the curvature of the second spring tube 28 within the shell 211.
In some embodiments, materials with less friction including but not limited to Poly tetra fluoroethylene (PTFE) can be disposed on the inner walls of the first spring tube 26 and the second spring tube 28, in order to solve the friction loss during transmission.
In the present embodiment, the actuator 21 is provided with a T-shape slot 212, the connecting element 22 is locked into the T-shape slot 212 and fixed with the actuator 21 as shown in
Referring to
As an improvement of the present invention, the robotic dexterous hand 100 further includes a suction mounting portion 50, the suction mounting portion 50 is positioned on one of the actuators 21 and used for mounting a sucker. The suction mounting portion 50 allows the robotic dexterous hand 100 to suck some objects that the fingers 23 are not easy to catch, thereby promoting the ability of the robotic dexterous hand 100 to grip the objects.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
10786907, | Oct 28 2016 | SHENZHEN DORABOT ROBOTICS CO , LTD | Manipulator and robot with fingertip module |
3694021, | |||
8100451, | Nov 24 2006 | Panasonic Corporation | Multi-fingered robot hand |
8597370, | Jul 09 2009 | FTNON ALMELO B V | Artificial hand |
20120013139, | |||
20140334907, |
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